Arnab Ghosh

@iitb.ac.in

Department of Energy Science and Engineering
Indian Institute of Technology Bombay

Arnab Ghosh


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https://researchid.co/arnabghosh

EDUCATION

- PhD in Energy Science and Engineering (Indian Institute of Technology Bombay)
- M.Sc. in Chemistry (Indian Institute of Technology Hyderabad)
- B.Sc. in Chemistry (University of Burdwan)

RESEARCH INTERESTS

Lithium-ion batteries, Lithium-sulfur batteries, Sodium-sulfur batteries
34

Scopus Publications

1582

Scholar Citations

21

Scholar h-index

29

Scholar i10-index

Scopus Publications

  • The Iceberg of Lithium-Ion Battery Safety: The Indirect Relationship Between Electrolyte Flammability and Fire Behavior
    Mingyang Zhang, Yi He, Xiang Ao, Arnab Ghosh, Xingmin He, et al.
    Advanced Functional Materials, 2026
    The safety of electrolytes plays a pivotal role in determining the overall performance of lithium‐ion batteries, yet current safety evaluations focus mainly on the material level, overlooking behavior under practical battery operating conditions. Despite increasing recognition that the intrinsic flame retardancy of electrolytes does not directly translate into the overall fire resistance of lithium‐ion batteries, the mechanistic origins of this non‐equivalent relationship remain insufficiently understood. To bridge this knowledge gap, we systematically evaluate the fire behavior of pouch cells incorporating three representative flame‐retardant carbonate‐based electrolytes using cone calorimetry. Notably, flame retardants that perform exceptionally well at the electrolyte scale fail to yield meaningful improvements in battery‐level fire safety, whereas electrolytes with only moderate intrinsic retardancy can endow the full cell with nonflammability. Finite element simulations further clarify the fundamental disparities in combustion pathways between isolated electrolytes and full cells. These findings reveal the underlying causes of the indirect correlation between carbonate‐based electrolyte and cell‐level safety and advocate a paradigm shift from isolated component analyses to holistic, cell‐level safety strategies as the foundation for next‐generation inherently safe batteries.
  • Sulfur-Rich Sustainable Copolymers for Enhancing Redox Kinetics and Alleviating Cathode Passivation in Lithium-Sulfur Batteries
    Sangeeta Sahu, Arnab Ghosh, Monisha Monisha, Murali Krishna, Shakir Ali Siddiqui, et al.
    Exploration, 2026
    Lithium‐sulfur (Li‐S) batteries are promising candidates for advanced energy storage systems. However, their performance is hindered by uncontrolled cathode passivation due to the formation of electronically insulating lithium sulfide (Li 2 S). Here, we report a sulfur‐rich copolymer, poly(sulfur‐ random ‐cardanol cystamine) [poly(S‐ r ‐Ccys)], as an efficient cathode material that enables spatially regulated Li 2 S growth and improved redox kinetics. The nitrogen and oxygen functionalities in the Ccys moiety facilitate electrostatic interactions with lithium polysulfides, enhancing their dissolution and redistribution. Pulsed‐field gradient nuclear magnetic resonance measurements confirm improved Li + ion diffusion, while galvanostatic intermittent titration technique analysis reveals faster reaction kinetics in the poly(S‐ r ‐Ccys) cathode. The poly(S‐ r ‐Ccys) cathodes exhibit superior cycling stability compared to conventional elemental sulfur cathodes, maintaining 76.7% of their initial capacity after 300 cycles at 1 C, with a low average capacity fade of just 0.077% per cycle. This work demonstrates that poly(S‐ r ‐Ccys) offers a viable strategy to overcome Li 2 S deposition challenges and improve the cycle life of Li‐S batteries without altering the conventional ether‐based electrolyte system.
  • Deciphering a New Electrolyte Formulation for Intelligent Modulation of Thermal Runaway to Improve the Safety of Lithium-Ion Batteries
    Arnab Ghosh, Sunan Tian, Mingyang Zhang, Isaac Lorero Gómez, Qi Chen, et al.
    Advanced Functional Materials, 2025
    Thermal runaway remains a persisting challenge that poses a significant risk to lithium‐ion battery (LIB) users. In commercial LIBs, thermal runaway is typically controlled using temperature‐responsive trilayer polypropylene/polyethylene/polypropylene (PP/PE/PP) separators. However, because of thermal shrinkage at ≈160 °C, these separators often fail to prevent thermal runaway in practical LIBs. Electrolyte engineering is, therefore, crucial to mitigate the risk of thermal runaway in LIBs. In this context, the Diels‐Alder click chemistry is being introduced to tackle the thermal runaway issues in LIBs. A thermoresponsive electrolyte is proposed composed of a lithium salt dissolved in vinylene carbonate (VC) and 2,5‐dimethylfuran (DMFu) that functions effectively in batteries at room temperature. At high temperatures, VC and DMFu participate in Diels‐Alder reactions, forming oligomers that significantly decrease the ionic conductivity of the electrolyte and concurrently occlude the micropores of PP/PE/PP separators. These dual effects enable a two‐step intelligent modulation of thermal runaway, with a warning phase activated above 80 °C and a complete thermal shutdown at 120 °C. The thermoresponsive electrolyte formulation deciphered in this study holds great potential for advancing the safety of LIBs through electrolyte engineering.
  • Alpha-cyclodextrin-based polyrotaxane combining phytate lithium salt as a novel bio-based flame-retardant solid polymer electrolyte for all-solid-state lithium metal batteries
    Qi Chen, Arnab Ghosh, Wei Tang, Guang-Zhong Yin, Juan P. Fernández-Blázquez, et al.
    Chemical Engineering Journal, 2025
  • Localized High-Concentration Binary Salt Electrolytes with Suppressed Li2Sx Solubility to Achieve Stable Li-S Pouch Cells with High Sulfur-Loading Cathodes under Lean Electrolyte Conditions
    Jiali Liu, Arnab Ghosh, Shinji Kondou, Shanglin Li, Kazuhide Ueno, et al.
    ACS Applied Energy Materials, 2025
  • Enhanced Performance of Laser-Induced Graphene Supercapacitors via Integration with Candle-Soot Nanoparticles
    Arnab Ghosh, Sukhman Kaur, Gulshan Verma, Christian Dolle, Raheleh Azmi, et al.
    ACS Applied Materials and Interfaces, 2024
    Laser-induced graphene (LIG) has been emerging as a promising electrode material for supercapacitors due to its cost-effective and straightforward fabrication approach. However, LIG-based supercapacitors still face challenges with limited capacitance and stability. To overcome these limitations, in this work, we present a novel, cost-effective, and facile fabrication approach by integrating LIG materials with candle-soot nanoparticles. The composite electrode is fabricated by laser irradiation on a Kapton sheet to generate LIG material, followed by spray-coating with candle-soot nanoparticles and annealing. Materials characterization reveals that the annealing process enables a robust connection between the nanoparticles and the LIG materials and enhances nanoparticle graphitization. The prepared supercapacitor yields a maximum specific capacitance of 15.1 mF/cm2 at 0.1 mA/cm2, with a maximum energy density of 2.1 μWh/cm2 and a power density of 50 μW/cm2. Notably, the synergistic activity of candle soot and LIG surpasses the performances of previously reported LIG-based supercapacitors. Furthermore, the cyclic stability of the device demonstrates excellent capacitance retention of 80% and Coulombic efficiency of 100% over 10000 cycles.
  • Flame retardant properties of metal hydroxide-based polymer composites: A machine learning approach
    Junchen Xiao, Jose Hobson, Arnab Ghosh, Maciej Haranczyk, De-Yi Wang
    Composites Communications, 2023
  • Lithium Aluminate Nanoflakes as an Additive to Sulfur Cathodes for Enhanced Mass Transport in High-Energy-Density Lithium-Sulfur Pouch Cells Utilizing Sparingly Solvating Electrolytes
    Arnab Ghosh, Jiali Liu, Shanglin Li, Kazuhide Ueno, Kaoru Dokko, et al.
    ACS Applied Materials and Interfaces, 2023
    The utilization of sparingly solvating electrolytes has been reckoned as a promising approach to realizing high-energy-density lithium-sulfur batteries under lean electrolyte conditions through decoupling the electrolyte amount from sulfur utilization. However, the inferior wettability of high-concentration sparingly solvating electrolytes compromises mass transport, thereby impeding the maximum utilization of active material in sulfur cathodes. To address this issue, in this study, we incorporate lithium aluminate (LiAlO2) nanoflakes as an additive to sulfur cathodes to enhance the mass transport by improving the percolation and accessibility of sparingly solvating electrolytes to the bulk of the electrodes. The electrochemical kinetics of LiAlO2-containing sulfur cathodes are investigated using the galvanostatic intermittent titration technique. The Li+ self-diffusion coefficients of electrode materials were estimated through pulsed-field gradient nuclear magnetic resonance (PFG-NMR) spectroscopy. Finally, a 193 Wh kg-1 Li-S pouch cell (excluding the mass of the laminated Al pouch) is demonstrated by utilizing the LiAlO2-incorporated sulfur cathode with a high S-loading of 4.3 mg cm-2 in a low electrolyte/sulfur (E/S) ratio of 3 μL mg-1. The Li-S pouch cell retains 80% of its initial specific cell capacity after 50 cycles. Our comprehensive understanding of the role of LiAlO2 additives in enhancing the mass transport and Li+ self-diffusion coefficient of sulfur cathodes will contribute immensely toward the development of high-energy-density Li-S batteries under lean electrolyte conditions.
  • Carbonaceous-Material-Induced Gelation of Concentrated Electrolyte Solutions for Application in Lithium-Sulfur Battery Cathodes
    Ryo Motoyoshi, Shanglin Li, Seiji Tsuzuki, Arnab Ghosh, Kazuhide Ueno, et al.
    ACS Applied Materials and Interfaces, 2022
    Lithium-sulfur (Li-S) batteries can theoretically deliver high energy densities exceeding 2500 Wh kg-1. However, high sulfur loading and lean electrolyte conditions are two major requirements to enhance the actual energy density of the Li-S batteries. Herein, the use of carbon-dispersed highly concentrated electrolyte (HCE) gels with sparingly solvating characteristics as sulfur hosts in Li-S batteries is proposed as a unique approach to construct continuous electron-transport and ion-conduction paths in sulfur cathodes as well as achieve high energy density under lean-electrolyte conditions. The sol-gel behavior of carbon-dispersed sulfolane-based HCEs was investigated using phase diagrams. The sol-to-gel transition was mainly dependent on the amount of the carbonaceous material and the Li salt content. The gelation was caused by the carbonaceous-material-induced formation of an integrated network. Density functional theory (DFT) calculations revealed that the strong cation-π interactions between Li+ and the induced dipole of graphitic carbon were responsible for facilitating the dispersion of the carbonaceous material into the HCEs, thereby permitting gel formation at high Li-salt concentrations. The as-prepared carbon-dispersed sulfolane-based composite gels were employed as efficient sulfur hosts in Li-S batteries. The use of gel-type sulfur hosts eliminates the requirement for excess electrolytes and thus facilitates the practical realization of Li-S batteries under lean-electrolyte conditions. A Li-S pouch cell that achieved a high cell-energy density (up to 253 Wh kg-1) at a high sulfur loading (4.1 mg cm-2) and low electrolyte/sulfur ratio (4.2 μL mg-1) was developed. Furthermore, a Li-S polymer battery was fabricated by combining the composite gel cathode and a polymer gel electrolyte.
  • Electrocatalytic Activity of Polyaniline in Magnesium-Sulfur Batteries
    Murali Krishna, Arnab Ghosh, Divyamahalakshmi Muthuraj, Sharmistha Das, Sagar Mitra
    Journal of Physical Chemistry Letters, 2022
    Rechargeable magnesium-sulfur (Mg-S) batteries offer the potential for inexpensive energy storage alternatives to other metal-ion batteries for the grid scale and household applications. Despite all economic and resource advantages, Mg-S battery chemistry suffers from a complicated reaction mechanism and extremely slow reaction kinetics. To improve the kinetics, we improvise a new electrode architecture where a conductive polymer is used along with a carbon network. This report will bring an important insight of electrocatalytic activity of polyaniline, on the basis of free-radical coupling and is a completely new concept in Mg-S battery chemistry. By the combined electron spin resonance spectroscopy, X-ray photoelectron spectroscopy, and fluorescence lifetime measurements, we perceived that the polyaniline anchors the S3•- species from the electrolyte/catholyte through a free-radical-coupling process and thus promotes the reduction to end-discharged products, via a chemical adduct. The concept of free-radical catalysis in Mg/S batteries will open a new knowledge to enhance the active material utilization in the Mg-S batteries.
  • Sub-zero and room-temperature sodium–sulfur battery cell operations: A rational current collector, catalyst and sulphur-host design and study
    Ajit Kumar, Arnab Ghosh, Arpita Ghosh, Aakash Ahuja, Abhinanda Sengupta, et al.
    Energy Storage Materials, 2021
  • Simple route to lithium dendrite prevention for long cycle-life lithium metal batteries
    Arnab Ghosh, Pavel Cherepanov, Cuong Nguyen, Arpita Ghosh, Ajit Kumar, et al.
    Applied Materials Today, 2021
  • Magnesium polysulfide catholyte (MgSx): Synthesis, electrochemical and computational study for magnesium-sulfur battery application
    Divyamahalakshmi Muthuraj, Madhu Pandey, Murali Krishna, Arnab Ghosh, Raja Sen, et al.
    Journal of Power Sources, 2021
  • Approach to Increase the Utilization of Active Material in a High Sulfur-Loaded Cathode for High Areal Capacity Room-Temperature Sodium-Sulfur Batteries
    Ajit Kumar, Arnab Ghosh, Arpita Ghosh, Aakash Ahuja, Maria Forsyth, et al.
    ACS Applied Energy Materials, 2021
  • Lewis Acid–Base Interactions between Polysulfides and Boehmite Enables Stable Room-Temperature Sodium–Sulfur Batteries
    Arnab Ghosh, Ajit Kumar, Tisita Das, Arpita Ghosh, Sudip Chakraborty, et al.
    Advanced Functional Materials, 2020
  • Halogen-free flame-retardant sulfur copolymers with stable Li–S battery performance
    Monisha Monisha, Preetham Permude, Arnab Ghosh, Ajit Kumar, Saad Zafar, et al.
    Energy Storage Materials, 2020
  • Ultrathin Lithium Aluminate Nanoflake-Inlaid Sulfur as a Cathode Material for Lithium-Sulfur Batteries with High Areal Capacity
    Arnab Ghosh, Ajit Kumar, Amlan Roy, Cuong Nguyen, Aakash Ahuja, et al.
    ACS Applied Energy Materials, 2020
  • Free-Radical Catalysis and Enhancement of the Redox Kinetics for Room-Temperature Sodium-Sulfur Batteries
    Ajit Kumar, Arnab Ghosh, Maria Forsyth, Douglas R. MacFarlane, Sagar Mitra
    ACS Energy Letters, 2020
  • A novel chemical reduction/co-precipitation method to prepare sulfur functionalized reduced graphene oxide for lithium-sulfur batteries
    Pravin H. Wadekar, Arnab Ghosh, Rahul V. Khose, Dattatray A. Pethsangave, Sagar Mitra, et al.
    Electrochimica Acta, 2020
  • Sodium-ion battery anode stabilization
    Prasit Kumar Dutta, Arnab Ghosh, Sagar Mitra
    Nanomaterials for Electrochemical Energy Storage Devices, 2019
  • Blocks of molybdenum ditelluride: A high rate anode for sodium-ion battery and full cell prototype study
    Manas Ranjan Panda, Anish Raj K, Arnab Ghosh, Ajit Kumar, Divyamahalakshmi Muthuraj, et al.
    Nano Energy, 2019
  • High-energy density room temperature sodium-sulfur battery enabled by sodium polysulfide catholyte and carbon cloth current collector decorated with MnO2 nanoarrays
    Ajit Kumar, Arnab Ghosh, Amlan Roy, Manas Ranjan Panda, Maria Forsyth, et al.
    Energy Storage Materials, 2019
  • Three-Dimensionally Reinforced Freestanding Cathode for High-Energy Room-Temperature Sodium-Sulfur Batteries
    Arnab Ghosh, Ajit Kumar, Amlan Roy, Manas Ranjan Panda, Mega Kar, et al.
    ACS Applied Materials and Interfaces, 2019
  • Nitrogen and Sulfur Doped Carbon Cloth as Current Collector and Polysulfide Immobilizer for Magnesium-Sulfur Batteries
    Divyamahalakshmi Muthuraj, Arnab Ghosh, Ajit Kumar, Sagar Mitra
    Chemelectrochem, 2019
  • A high-performance sodium anode composed of few-layer MoSe2 and N, P doped reduced graphene oxide composites
    Amlan Roy, Arnab Ghosh, Ajit Kumar, Sagar Mitra
    Inorganic Chemistry Frontiers, 2018

RECENT SCHOLAR PUBLICATIONS

  • The Iceberg of Lithium-Ion Battery Safety: The Indirect Relationship Between Electrolyte Flammability and Fire Behavior
    M Zhang, Y He, X Ao, A Ghosh, X He, J Hobson, P Tan, DY Wang
    Advanced Functional Materials , 2026
    2026
  • Deciphering a New Electrolyte Formulation for Intelligent Modulation of Thermal Runaway to Improve the Safety of Lithium-ion Batteries
    A Ghosh, S Tian, M Zhang, IL Gómez, Q Chen, M Islam, B Bhatia, ...
    Advanced Functional Materials , 2025
    2025
    Citations: 9
  • Alpha-cyclodextrin-based polyrotaxane combining phytate lithium salt as a novel bio-based flame-retardant solid polymer electrolyte for all-solid-state lithium metal batteries
    Q Chen, A Ghosh, W Tang, GZ Yin, JP Fernandez-Blazquez, M Zhang, ...
    Chemical Engineering Journal 512, 162376 , 2025
    2025
    Citations: 8
  • Localized High-Concentration Binary Salt Electrolytes with Suppressed Li2Sx Solubility to Achieve Stable Li–S Pouch Cells with High Sulfur-Loading Cathodes Under Lean …
    J Liu, A Ghosh, S Kondou, S Li, K Ueno, K Dokko, M Watanabe
    ACS Applied Energy Materials 8 (3), 1570–1579 , 2025
    2025
    Citations: 10
  • Enhanced Performance of Laser-Induced Graphene Supercapacitors via Integration with Candle-Soot Nanoparticles
    A Ghosh, S Kaur, G Verma, C Dolle, R Azmi, S Heissler, Y Eggeler, ...
    ACS Applied Materials & Interfaces 16 (31), 40313–40325 , 2024
    2024
    Citations: 28
  • Flame retardant properties of metal hydroxide-based polymer composites: A machine learning approach
    J Xiao, J Hobson, A Ghosh, M Haranczyk, DY Wang
    Composites Communications 40, 101593 , 2023
    2023
    Citations: 43
  • Lithium Aluminate Nanoflakes as an Additive to Sulfur Cathodes for Enhanced Mass Transport in High-Energy-Density Lithium–Sulfur Pouch Cells Utilizing Sparingly Solvating …
    A Ghosh, J Liu, S Li, K Ueno, K Dokko, M Watanabe
    ACS Applied Materials & Interfaces 15 (19), 23104–23114 , 2023
    2023
    Citations: 10
  • Carbonaceous-Material-Induced Gelation of Concentrated Electrolyte Solutions for Application in Lithium–Sulfur Battery Cathodes
    R Motoyoshi, S Li, S Tsuzuki, A Ghosh, K Ueno, K Dokko, M Watanabe
    ACS Applied Materials & Interfaces 14 (40), 45403–45413 , 2022
    2022
    Citations: 11
  • Electrocatalytic Activity of Polyaniline in Magnesium–Sulfur Batteries
    M Krishna, A Ghosh, D Muthuraj, S Das, S Mitra
    The Journal of Physical Chemistry Letters 13 (5), 1337–1343 , 2022
    2022
    Citations: 15
  • Sub-zero and room-temperature sodium–sulfur battery cell operations: A rational current collector, catalyst and sulphur-host design and study
    A Kumar, A Ghosh, A Ghosh, A Ahuja, A Sengupta, M Forsyth, ...
    Energy Storage Materials 42, 608–617 , 2021
    2021
    Citations: 35
  • Metal oxide/sulfur composite cathodes for room temperature lithium-sulfur and sodium-sulfur batteries
    A Ghosh
    Monash University , 2021
    2021
  • Simple route to lithium dendrite prevention for long cycle-life lithium metal batteries
    A Ghosh, P Cherepanov, C Nguyen, A Ghosh, A Kumar, A Ahuja, M Kar, ...
    Applied Materials Today 23, 101062 , 2021
    2021
    Citations: 17
  • Approach to Increase the Utilization of Active Material in a High Sulfur-Loaded Cathode for High Areal Capacity Room-Temperature Sodium–Sulfur Batteries
    A Kumar, A Ghosh, A Ghosh, A Ahuja, M Forsyth, D MacFarlane, S Mitra
    ACS Applied Energy Materials 4 (1), 384–393 , 2021
    2021
    Citations: 27
  • Magnesium polysulfide catholyte (MgSx): Synthesis, electrochemical and computational study for magnesium-sulfur battery application
    D Muthuraj, M Pandey, M Krishna, A Ghosh, R Sen, P Johari, S Mitra
    Journal of Power Sources 486, 229326 , 2020
    2020
    Citations: 38
  • Lewis Acid–Base Interactions between Polysulfides and Boehmite Enables Stable Room‐Temperature Sodium–Sulfur Batteries
    A Ghosh, A Kumar, T Das, A Ghosh, S Chakraborty, M Kar, D MacFarlane, ...
    Advanced Functional Materials 30 (50), 2005669 , 2020
    2020
    Citations: 62
  • Free-Radical Catalysis and Enhancement of the Redox Kinetics for Room-Temperature Sodium–Sulfur Batteries
    A Kumar, A Ghosh, M Forsyth, D MacFarlane, S Mitra
    ACS Energy Letters 5 (6), 2112–2121 , 2020
    2020
    Citations: 60
  • Ultrathin Lithium Aluminate Nanoflake-Inlaid Sulfur as a Cathode Material for Lithium−Sulfur Batteries with High Areal Capacity
    A Ghosh, A Kumar, A Roy, C Nguyen, A Ahuja, M Adil, M Chatti, M Kar, ...
    ACS Applied Energy Materials 3 (6), 5637–5645 , 2020
    2020
    Citations: 14
  • Halogen-free flame-retardant sulfur copolymers with stable Li–S battery performance
    M Monisha, P Permude, A Ghosh, A Kumar, S Zafar, S Mitra, B Lochab
    Energy Storage Materials 29, 350–360 , 2020
    2020
    Citations: 50
  • A novel chemical reduction/co-precipitation method to prepare sulfur functionalized reduced graphene oxide for lithium-sulfur batteries
    P Wadekar, A Ghosh, R Khose, P Dattatray, S Mitra, S Some
    Electrochimica Acta 344, 136147 , 2020
    2020
    Citations: 44
  • Cathode electrode for lithium-sulfur batteries
    A Ghosh, A Kumar, M Kar, D MacFarlane, S Mitra
    IN Patent 469,736 , 2019
    2019

MOST CITED SCHOLAR PUBLICATIONS

  • Covalent organic framework-based microspheres as anode material for rechargeable sodium batteries
    B Patra, SK Das, A Ghosh, A Raj, P Moitra, M Addicoat, S Mitra, ...
    Journal of Materials Chemistry A 6, 16655–16663 , 2018
    2018
    Citations: 163
  • Sulfur Copolymer: A New Cathode Structure for Room-Temperature Sodium–Sulfur Batteries
    A Ghosh, S Shukla, M Monisha, A Kumar, B Lochab, S Mitra
    ACS Energy Letters 2 (10), 2478–2485 , 2017
    2017
    Citations: 150
  • High-energy density room temperature sodium-sulfur battery enabled by sodium polysulfide catholyte and carbon cloth current collector decorated with MnO2 nanoarrays
    A Kumar, A Ghosh, A Roy, MR Panda, M Forsyth, D MacFarlane, S Mitra
    Energy Storage Materials 20, 196–202 , 2019
    2019
    Citations: 119
  • Blocks of molybdenum ditelluride: A high rate anode for sodium-ion battery and full-cell prototype study
    MR Panda, AK Raj, A Ghosh, A Kumar, D Muthuraj, S Sau, W Yu, Y Zhang, ...
    Nano Energy 64, 103951 , 2019
    2019
    Citations: 95
  • Cardanol benzoxazines–A sustainable linker for elemental sulphur based copolymers via inverse vulcanisation
    S Shukla, A Ghosh, PK Roy, S Mitra, B Lochab
    Polymer 99, 349–357 , 2016
    2016
    Citations: 95
  • Sustainable Sulfur-rich Copolymer/Graphene Composite as Lithium-Sulfur Battery Cathode with Excellent Electrochemical Performance
    A Ghosh, S Shukla, GS Khosla, B Lochab, S Mitra
    Scientific Reports 6, 25207 , 2016
    2016
    Citations: 90
  • Three-Dimensionally Reinforced Freestanding Cathode for High-Energy Room-Temperature Sodium–Sulfur Batteries
    A Ghosh, A Kumar, A Roy, MR Panda, M Kar, DR MacFarlane, S Mitra
    ACS Applied Materials & Interfaces 11 (15), 14101–14109 , 2019
    2019
    Citations: 80
  • Cardanol benzoxazine‐Sulfur Copolymers for Li‐S batteries: Symbiosis of Sustainability and Performance
    S Shukla, A Ghosh, UK Sen, PK Roy, S Mitra, B Lochab
    ChemistrySelect 1 (3), 594–600 , 2016
    2016
    Citations: 70
  • Nitrogen and Sulfur Doped Carbon Cloth as Current Collector and Polysulfide Immobilizer for Magnesium‐Sulfur Batteries
    D Muthuraj, A Ghosh, A Kumar, S Mitra
    ChemElectroChem 6 (3), 684–689 , 2018
    2018
    Citations: 63
  • Lewis Acid–Base Interactions between Polysulfides and Boehmite Enables Stable Room‐Temperature Sodium–Sulfur Batteries
    A Ghosh, A Kumar, T Das, A Ghosh, S Chakraborty, M Kar, D MacFarlane, ...
    Advanced Functional Materials 30 (50), 2005669 , 2020
    2020
    Citations: 62
  • A high-performance sodium anode composed of few-layer MoSe2 and N, P doped reduced graphene oxide composites
    A Roy, A Ghosh, A Kumar, S Mitra
    Inorganic Chemistry Frontiers 5, 2189–2197 , 2018
    2018
    Citations: 62
  • Free-Radical Catalysis and Enhancement of the Redox Kinetics for Room-Temperature Sodium–Sulfur Batteries
    A Kumar, A Ghosh, M Forsyth, D MacFarlane, S Mitra
    ACS Energy Letters 5 (6), 2112–2121 , 2020
    2020
    Citations: 60
  • A Facile Bottom-up Approach to Construct Hybrid Flexible Cathode Scaffold for High Performance Lithium-Sulfur Batteries
    A Ghosh, R Manjunatha, R Kumar, S Mitra
    ACS Applied Materials & Interfaces 8 (49), 33775–33785 , 2016
    2016
    Citations: 53
  • Halogen-free flame-retardant sulfur copolymers with stable Li–S battery performance
    M Monisha, P Permude, A Ghosh, A Kumar, S Zafar, S Mitra, B Lochab
    Energy Storage Materials 29, 350–360 , 2020
    2020
    Citations: 50
  • A novel chemical reduction/co-precipitation method to prepare sulfur functionalized reduced graphene oxide for lithium-sulfur batteries
    P Wadekar, A Ghosh, R Khose, P Dattatray, S Mitra, S Some
    Electrochimica Acta 344, 136147 , 2020
    2020
    Citations: 44
  • Flame retardant properties of metal hydroxide-based polymer composites: A machine learning approach
    J Xiao, J Hobson, A Ghosh, M Haranczyk, DY Wang
    Composites Communications 40, 101593 , 2023
    2023
    Citations: 43
  • Magnesium polysulfide catholyte (MgSx): Synthesis, electrochemical and computational study for magnesium-sulfur battery application
    D Muthuraj, M Pandey, M Krishna, A Ghosh, R Sen, P Johari, S Mitra
    Journal of Power Sources 486, 229326 , 2020
    2020
    Citations: 38
  • Sub-zero and room-temperature sodium–sulfur battery cell operations: A rational current collector, catalyst and sulphur-host design and study
    A Kumar, A Ghosh, A Ghosh, A Ahuja, A Sengupta, M Forsyth, ...
    Energy Storage Materials 42, 608–617 , 2021
    2021
    Citations: 35
  • Enhanced electrochromic write–erase efficiency of a device with a novel viologen: 1, 1′-bis (2-(1H-indol-3-yl) ethyl)-4, 4′-bipyridinium diperchlorate
    R Sydam, A Ghosh, M Deepa
    Organic Electronics 17, 33–43 , 2015
    2015
    Citations: 35
  • Enhanced Performance of Laser-Induced Graphene Supercapacitors via Integration with Candle-Soot Nanoparticles
    A Ghosh, S Kaur, G Verma, C Dolle, R Azmi, S Heissler, Y Eggeler, ...
    ACS Applied Materials & Interfaces 16 (31), 40313–40325 , 2024
    2024
    Citations: 28